CN111061041A - Auto-focus and optical image stabilization in compact folded cameras - Google Patents

Abstract

Compact folded camera modules with Autofocus (AF) and Optical Image Stabilization (OIS) capabilities and multi-aperture cameras including these modules. In one embodiment, a folded camera module includes an Optical Path Folding Element (OPFE) for folding light from a first optical path having a first optical axis to a second optical path having a second optical axis perpendicular to the first optical axis; an image sensor; and a lens module carrying a lens having a symmetry axis parallel to the second optical axis. The lens module may be actuated to move in first and second orthogonal directions in a plane perpendicular to the first optical axis, the movement in the first direction being for auto-focus and the movement in the second direction being for OIS. The OPFE may be actuated to tilt for OIS.

Description

Auto-focus and optical image stabilization in compact folded cameras

Divisional application:

the patent application of the invention is a divisional application of PCT advanced Chinese patent application with the prior patent application number of 201680021706.3, the application date of 2016, 4 and 15, and the title of the invention is "automatic focusing and optical image stabilization in compact folding camera". International application No. PCT/IB2016/052179 corresponds to this application.

Cross-reference to related applications:

this application claims priority from U.S. provisional patent application No. 62/148,435 filed on 16/4/2015 and No. 62/238,890 filed on 8/10/2015, both of which have the same title and are expressly incorporated herein by reference in their entirety.

Technical Field

Embodiments disclosed herein relate generally to digital cameras and, more particularly, to folded lens digital cameras and bifocal digital cameras having a folded lens.

Background

In recent years, mobile devices such as mobile phones (particularly smart phones), tablet computers, and notebook computers have become ubiquitous. Many of these devices include one or two compact cameras including, for example, a rear-facing primary camera (i.e., a camera on the rear side of the device that is remote from the user and often used for casual photography) and a front-facing secondary camera (i.e., a camera on the front side of the device and often used for video conferencing).

Although relatively compact in nature, most of these cameras are similar in design to digital still cameras of conventional construction, i.e., they include a lens module (or series of several optical elements) placed on top of an image sensor. The lens module refracts and bends incident light rays to create an image of the scene on the sensor. The size of these cameras depends to a large extent on the size of the sensor and the height of the optical elements. These are usually combined by the focal length ("f") of the lens and its field of view (FOV), where a lens that must image a certain FOV on a certain size sensor has a specific focal length. To keep the FOV constant, the larger the sensor size (e.g., in the X-Y plane), the larger the focal length and optical height.

A "folded camera module" structure has recently been proposed to reduce the height of compact cameras. In the folded camera module structure, an optical path folding element (hereinafter referred to as "OPFE"), such as a prism or a mirror (otherwise collectively referred to herein as "reflecting element"), is added to tilt the light propagation direction from perpendicular to the back of the smartphone to parallel to the back of the smartphone. If the folded camera module is part of a dual aperture camera, this provides a folded light path through a lens module (e.g., a telephoto lens). Such cameras are referred to herein as "folded lens dual aperture cameras" or "dual aperture cameras with folded lenses". In general, a folded camera module may be included in a multi-aperture camera, for example, in a three-aperture camera with two "unfolded" camera modules.

In addition to the lens module and the sensor, modern cameras typically further comprise a mechanical movement (actuation) mechanism, mainly for two purposes: image focusing on the sensor and Optical Image Stabilization (OIS). For focusing, in more advanced cameras, the position of the lens module (or at least the lens elements in the lens module) may be changed by means of an actuator, and the focusing distance may be changed depending on the captured object or scene.

The trend in digital still cameras is to increase the zoom capability (e.g., to 5x, 10x, or more), while in cell phone (especially smart phone) cameras, to reduce the sensor pixel size and increase the number of pixels. These trends result in greater sensitivity to camera shake for two reasons: 1) higher resolution, and 2) longer exposure time due to smaller sensor pixels. OIS mechanisms are needed to mitigate this effect.

In the OlS-enabled camera, the lateral position of the lens module may be moved, or the entire camera module may be quickly tilted to counteract camera shake during image capture. Camera shake will shift the camera module by 6 degrees of freedom, i.e., linear movement in X-Y-Z, rotation of the X-axis ("tilt about" or "around" the X-axis), yaw (tilt around the Z-axis), and pitch (tilt around the Y-axis). Although the effect of the linear motion in X-Y-Z on the image quality is negligible and no compensation is required, the tilt angle needs to be compensated for. The OIS system shown in the known design (see e.g. US20140327965a1) corrects for yaw and pitch but not for roll motion.

Folded lens dual aperture cameras with an Autofocus (AF) mechanism are disclosed in applicant's US published patent application US20160044247, the specification and drawings of which are incorporated herein by reference in their entirety.

Disclosure of Invention

Fig. 1 shows a schematic diagram providing a design of a "low height" folded camera module. The figure shows a folded camera module 100 comprising an OPFE 102, a lens module 104 configured to mechanically hold a lens element therein, and an image sensor 106.

OPFE 102 can be, for example, any one of a mirror, a prism, or a prism covered with a metal reflective surface. OPFE 102 may be made of a variety of materials including, for example, plastic, glass, reflective metal, or a combination of two or more of these materials. According to some non-limiting examples, the lens module in camera 100 has a 6mm to 15mm focal length ("tele lens") and it may be assembled in a dual-aperture camera with a second unfolded camera module having a 3mm to 5mm focal length ("wide lens") lens and a second sensor (not shown).

The AF function for the telephoto lens is realized by moving the lens module 104 along the Z axis. Applicants have discovered that OIS functionality for the camera 100 can be implemented in at least two ways. To compensate for tilt of the camera about the Z-axis, the lens module 104 may be shifted in the Y-direction and/or the OPFE 102 may be tilted about the Z-axis or the X-axis. However, optical analysis by the applicant has shown that tilting of the OPFE about the Z-axis also causes the image to undesirably tilt (rotate) on the sensor 106 about the Z-axis. This solution is lacking because it contradicts the basic idea behind the OIS function and because the computational fusion time is also increased due to the image difference of the tele and wide sensors (needed in a dual-aperture camera for producing a fused image from the fusion of the wide image generated by the wide lens and the tele image generated by the tele lens).

Applicants further discovered that to compensate for camera tilt about the Y-axis, the lens module can be moved in the X-direction and/or the OPFE can be tilted about the Y-axis. However, the applicant has also found that when shifting the lens module in the X direction, the module height will increase. For lenses with a diameter of 6mm to 6.5mm, shifting the lens module in the X direction for OIS and focusing in the Z direction may require increasing the module height to about 9mm to 9.5mm, as is the case with known OIS solutions. This increase in height is directly reflected in the thickness of the handset, which is undesirable in accordance with the design requirements of modern smart phones.

Accordingly, the presently disclosed subject matter includes a folded camera module that includes AF and OIS mechanisms in a manner that allows for the desired height of the folded camera module to be maintained. Furthermore, incorporating such mechanisms and capabilities does not result in camera height constraints. The disclosed subject matter further contemplates a folded lens, dual-aperture camera incorporating such folded camera modules.

Embodiments disclosed herein teach a folded camera module and a folded lens dual aperture camera, wherein the OIS function is divided between two optical elements as follows: the folded lens module shifts along one axis (e.g., Y-axis) and the OPFE rotates about an axis parallel to the same axis.

In one embodiment, a folded camera module is provided that includes an OPFE for folding light from a first optical path to a second optical path, the second optical path along a second optical axis. The folded camera module further comprises an image sensor, and a lens module carrying a lens assembly having an axis of symmetry along a second optical axis, wherein the lens module is designed to move in a first direction and a second direction orthogonal to the first direction, the first and second directions being in a plane containing the second optical axis and perpendicular to a plane containing the first and second optical paths, and wherein the OPFE is designed to tilt around the second direction.

Note that as used herein, "tilted about a direction" means tilted about a line or axis in or parallel to the direction.

In one embodiment, movement of the lens module in a first direction along the second optical axis is used for AF, and movement of the lens module in a second direction orthogonal to the first direction is used for OIS, so as to compensate for tilt of the camera module about the first direction.

In one embodiment, the movement of the OPFE is used for OIS to compensate for the tilt of the camera module about the second direction.

In one embodiment, the folded camera module further comprises a lens actuation subassembly configured to cause the lens module to move in first and second directions; and an OPFE actuation subassembly configured to cause movement of the OPFE to tilt the first optical path.

In one embodiment, each of the lens actuation sub-assembly and the OPFE actuation sub-assembly includes a plurality of flexible suspension members.

In one embodiment, the flexible suspension members of the lens actuation sub-assembly are parallel to each other.

In one embodiment, the flexible suspension member of the OPFE actuation subassembly is angled.

In one embodiment, the folded camera module further includes an actuation controller configured to receive a data input indicative of tilt in at least one direction and a data input from a position sensor coupled to the lens actuation subassembly, and, in response to the data input, configured to generate instructions to the lens actuation subassembly to cause movement in a second direction for Optical Image Stabilization (OIS).

In one embodiment, the actuation controller is further configured to receive a data input indicative of tilt in at least one direction and a data input from a position sensor coupled to the OPFE actuation subassembly, and in response to the data input, configured to generate an instruction to the OPFE actuation subassembly to cause the OPFE to move for OIS.

In one embodiment, the actuation controller is further configured to receive a data input indicative of the focal point and, in response to the data input, configured to generate instructions to the lens actuation subassembly to cause movement in a first direction to perform AF.

In one embodiment, the movement of the OPFE for tilting is about an axis perpendicular to the first and second optical directions.

In one embodiment, the movement of the lens module in the first direction is parallel to the second optical axis, and the movement of the lens module in the second direction is perpendicular to the second optical axis.

In one embodiment, the OPFE comprises a prism.

In one embodiment, the OPFE includes a mirror.

In one embodiment, the lens actuation subassembly includes a plurality of coil-magnet pairs for actuating movement of the lens module in the first and second directions.

In one embodiment, the plurality of coil-magnet pairs includes two coil-magnet pairs.

In one embodiment, the plurality of coil-magnet pairs includes three coil-magnet pairs.

In one embodiment, the plurality of coil-magnet pairs comprises four coil-magnet pairs.

In one embodiment, at least one of the four coil-magnet pairs is located between the lens module and the image sensor.

In one embodiment, the camera module further comprises one or more position sensors associated with the coil-magnet pair, the one or more position sensors enabling measurement of the position of the lens module.

In one embodiment, one or more position sensors enable measurement of the position of the lens module along the first and second directions of movement.

In one embodiment, the one or more position sensors further enable measurement of the position of the lens module with tilt about an axis perpendicular to the first and second directions of movement.

In one embodiment, a position sensor is coupled to the lens actuation subassembly and to the actuation controller to allow movement of the lens module in the first and second directions of movement while preventing tilting about an axis perpendicular to the first and second directions of movement.

In one embodiment, the one or more position sensors include hall bar sensors.

In one embodiment, two or three coil-magnet pairs are arranged to passively prevent unwanted tilting about an axis lying in a plane containing the first and second optical paths and perpendicular to the second optical axis.

In one embodiment, the three coil-magnet pairs are arranged to actively prevent unwanted tilting about an axis lying in a plane containing the first and second optical paths and perpendicular to the second optical axis.

In one embodiment, a dual-aperture camera is provided that includes the folded camera module of any of the above embodiments and a non-folded camera module that includes a non-folded camera image sensor and a non-folded camera lens module having a lens axis along a first optical axis that is perpendicular to a second optical axis.

The presently disclosed subject matter further contemplates a multi-aperture camera comprising three or more camera modules, wherein at least one of the camera modules is a folded camera module as described above, and any of the other camera modules may be a folded camera module or a non-folded camera module.

The disclosed subject matter further includes a method of compensating for tilt in a folded camera module comprising an OPFE, a lens module carrying a lens assembly, and an image sensor, the method comprising: folding light from a first optical path to a second optical path using OPFE, the second optical path along a second optical axis, the lens module having an axis of symmetry along the second optical axis; moving the lens module in a first direction and in a second direction orthogonal to the first direction, the first and second directions being in a plane containing the second optical axis and perpendicular to a plane containing the first and second optical paths, wherein movement of the lens module in the first direction is for auto-focus and movement of the lens module in the second direction orthogonal to the first direction is for OIS to compensate for tilt of the camera module about the first direction; and moving the OPFE to tilt about the second direction, wherein the movement of the OPFE is for OIS to compensate for the tilt of the camera module about the second direction.

Drawings

Non-limiting examples of the embodiments disclosed herein are described below with reference to the figures listed after this paragraph. The drawings and description are intended to illustrate and clarify embodiments disclosed herein and are not to be considered limiting in any way.

Like elements in different drawings may be denoted by like reference numerals. Elements in the drawings figures are not necessarily drawn to scale.

Fig. 1 shows a schematic diagram of a folded camera module including AF and OIS mechanisms in accordance with an example of the presently disclosed subject matter;

fig. 2A schematically illustrates an isometric view of a folded camera module including AF and OIS mechanisms in accordance with an example of the presently disclosed subject matter;

fig. 2B schematically illustrates a functional block diagram of a device including a folded camera module operable to perform AF and OIS, according to an example of the presently disclosed subject matter;

fig. 3A schematically illustrates an isometric view of a dual aperture camera including the folded camera module of fig. 2 and a second upright camera module, according to an example of the presently disclosed subject matter;

fig. 3B schematically illustrates an exterior view of a dual aperture camera including the folded camera module of fig. 2 and a second upright camera module, according to an example of the presently disclosed subject matter;

fig. 4 schematically illustrates an isometric view of the dual-aperture camera of fig. 3A with the folded lens module removed from its mount and inverted, according to an example of the presently disclosed subject matter;

fig. 5A shows an isometric exploded view of an embodiment of an OPFE actuation subassembly according to an example of the presently disclosed subject matter, wherein the OPFE is in the form of a prism;

fig. 5B illustrates a partial side view of the OPFE actuation sub-assembly of fig. 5A in accordance with an example of the presently disclosed subject matter;

fig. 5C shows an isometric exploded view of an OPFE actuation subassembly according to an example of the presently disclosed subject matter, wherein the OPFE is in the form of a prism;

fig. 5D illustrates a partial side view of the OPFE actuation sub-assembly of fig. 5C in accordance with an example of the presently disclosed subject matter;

fig. 5E schematically illustrates AF and OIS movement of a lens module and OIS tilt movement of an OPFE according to an example of the presently disclosed subject matter;

fig. 6 illustrates the following various views of another embodiment of an OPFE actuation sub-assembly according to an example of the presently disclosed subject matter: (a) an isometric view, (b) an exterior side view, (c) an interior side view, and (d) a bottom isometric view, wherein the OPFE is in the form of a prism;

fig. 7 shows details of an actuator in a folded camera module disclosed herein, according to an example of the presently disclosed subject matter;

FIG. 8 illustrates the actuator of FIG. 7 along section A-A shown in FIG. 7, according to an example of the presently disclosed subject matter;

FIG. 9 illustrates a magnetic simulation along the same A-A cut plane with arrows showing the magnetic field direction according to an example of the presently disclosed subject matter;

FIG. 10 shows an arrangement for lens actuation with three actuators according to an example of the presently disclosed subject matter;

FIG. 11 shows an arrangement for lens actuation with two actuators according to an example of the presently disclosed subject matter;

fig. 12A schematically illustrates an isometric view of another folded camera module including AF and OIS mechanisms in accordance with an example of the presently disclosed subject matter;

fig. 12B schematically illustrates an isometric view of the dual-aperture camera of fig. 12A with the folded lens module removed from its mount, according to an example of the presently disclosed subject matter;

fig. 12C schematically illustrates an isometric view of the dual-aperture camera of fig. 12A with the folded lens module (a) in a conventional view and (b) inverted, according to an example of the presently disclosed subject matter;

fig. 13 schematically illustrates a magnet in the folded lens module of fig. 12C, wherein the magnet is coated with an absorbing and scattering coating, according to an example of the presently disclosed subject matter.

Detailed Description

In the following description (and at least as shown in fig. 1), a reflective element (OPFE)208 reflects light from a first optical path or direction 205 to a second optical path or direction 206 (the latter converging with a second optical axis). Both the first and second optical directions define a plane (here the "first plane") containing both optical axes.

The following orthogonal X-Y-Z coordinate systems are chosen by way of example and are for illustrative purposes only: the Z axis is parallel (or coaxial) with a second optical axis, which is the axis of the folded camera module described below; the Y axis is orthogonal to the first optical axis and the second optical axis; the X-axis is orthogonal to the Y-axis and the Z-axis.

Fig. 2A schematically illustrates an isometric view of a folded camera module, numbered 200, according to an example of the presently disclosed subject matter. The folded camera module 200 includes an image sensor 202 having an imaging surface in the X-Y plane, a lens module 204 having an optical axis 206 defined above as "second optical axis", and an OPFE 208 having a surface plane 210 that is tilted to the image sensor surface, such that light arriving along a first optical path or direction 205 is tilted by the OPFE to the second optical axis or direction 206. The height of the dual aperture camera is indicated by H. H may be, for example, between 4mm and 7 mm.

Folded camera module 200 further includes a lens actuation subassembly 230 (shown in fig. 4) for moving lens module 204 in the Y-Z plane ("second plane"). Lens actuation subassembly 230 includes a lens barrel 214 (e.g., made of plastic) that houses lens element 204. Lens actuation subassembly 230 further includes a suspension structure that includes four flexible suspension members 216a-d (see fig. 4) that suspend lens barrel 214 from base 218. The members 216a-d are parallel to each other. In some embodiments, the members 216a-d may be in the form of four wires and may be referred to as "wire springs" or "rods". The suspension members 216a-d allow in-plane movement as known in the art and described, for example, in applicant's published PCT patent application No. WO2015/068056, the description and drawings of which are incorporated herein by reference in their entirety. The suspension structure with members 216a-d thus allows a first type of movement of the lens module relative to the base in a substantially Y-Z plane, actuated by the three actuators.

The actuator may be, for example, of the type sometimes referred to in the art as a "voice coil motor" (VCM). Lens actuation subassembly 230 further includes three magnets 222a-c (shown in FIG. 4), which are part of three magnetic structures (e.g., VCMs) referred to hereinafter as a first actuator, a second actuator, and a third actuator, respectively. Each actuator includes a coil in addition to the corresponding magnet. Thus, the first actuator includes a magnet 222a and a coil 224a, the second actuator includes a magnet 222b and a coil 224b, and the third actuator includes a magnet 222c and a coil 224 c.

The camera module 200 further includes an OPFE actuation subassembly that allows the OPFE 208 to tilt. A first embodiment of such an actuation subassembly, numbered 260, is shown in fig. 5A-E.

Fig. 2B schematically shows a functional block diagram of a device 250 including a folded camera module (such as module 200) operable to perform AF and OIS. The device may be, for example, a portable electronic device, such as a smartphone. In addition to the folded camera module 200, the device 250 also includes a gyroscope 262, an OIS \ AF actuation driver \ controller 264 (also referred to as an "actuation controller") and a portable device \ phone controller 266. The folded camera module shown includes the elements described above and below. OIS and AF performed by device (e.g., smartphone) 250 are described in detail below. In general, gyroscope 262 provides data input to controller 264 indicative of tilt in at least one direction. Similarly, position sensors 226a-c and 246 (the latter of which is described below) are configured to provide position inputs to driver/controller 264. Device/phone controller 266 is coupled to the image sensor and is configured to provide instructions to actuation controller 264. The instruction includes, for example, an AF required position and/or OIS switch on/off. Actuation controller 264 may provide actuation commands to actuation coils 224a-c and 244 (the latter described below) in response to data inputs from the gyroscopes and position sensors for generating motion that compensates for the detected tilt and/or for obtaining a desired focus position.

The folded camera module 200 may, for example, be included in a folded lens dual aperture camera as described in applicant's U.S. published patent application US 20160044247. Fig. 3A schematically illustrates an isometric view of a folded lens dual aperture camera 300 including the folded camera module of fig. 2 and a second upright camera module. Fig. 3B schematically shows an external view of the camera 300. In addition to the folded camera module 200, the camera 300 also includes an upright (unfolded) camera module 280 having a first optical axis 252 perpendicular to a second optical axis and a second plane.

For clarity, FIG. 4 shows camera 300 including folded camera module 200 with lens actuation subassembly 230 (including lens barrel 214 and its levers 216a-d) detached from base 218 and inverted, showing the underside with two plate portions 220a and 220 b. Three magnets 222a-c are positioned (e.g., rigidly assembled/mounted/glued) on the lower side plate portion.

Three corresponding coils 224a-c are positioned on the base 218. When lens actuation subassembly 230 is assembled, magnets 222a, 222b, and 222c are positioned directly above coils 224a, 224b, and 224 c. As described below (the "magnetically operative" portion), in operation, Lorentz forces may be exerted on the coil 224a in the Y-axis direction and on the two magnets 222b-c in the Z-axis direction. As described further below ("mechanical operation" section), the application of these three forces on the three magnets allows the center of mass of lens actuation subassembly 230 to move three mechanical degrees of freedom: linear Y and Z motion, and tilting motion about the X axis.

Movement of lens actuation subassembly 230 in the Y and Z directions (i.e., in the Y-Z plane) may be measured by position sensors, such as hall bar sensors (or simply "hall bars") 226a-c, which are coupled to magnetic fields generated by magnets 222a-c, respectively. As is known in the art, as the lens module moves in the Y-Z plane, the magnetic field sensed by the Hall bars 226a-c changes, and motion can be sensed at three points. This allows three types of movement to be determined, namely Y-direction movement, Z-direction movement and tilting about the X-axis.

Fig. 5A shows an isometric exploded view of OPFE actuated self-assembly 260 according to the disclosed subject matter. According to the example shown, OPFE actuation sub-assembly 260 includes hinge springs 236a-b that suspend the prism and may convert linear motion to angular motion. These hinge springs allow the prism 208 to tilt about a hinge axis 232 that is parallel to or along the Y-axis. The tilt may be, for example, ± 1 ° from the prism's null (rest position).

In the embodiment shown in fig. 5A, the hinge springs may be in the form of a single piece of flexible support 236a and 236b, each attached to one side of the prism. The prism and its reflective surface plane 210, hinge axis 232, and flexible support 236B are also shown in the side view of fig. 5B. The actuation sub-assembly 260 further includes an actuator 238 (hereinafter referred to as a "fourth" actuator) that includes a magnet 242 rigidly coupled to the prism 208 (in the illustrated example, via the adapter 215) and a coil 244 rigidly coupled to the base 212.

As regards the hinge spring, it can be designed in at least two different ways. In one design mentioned and shown in fig. 5A and 5B, the hinge spring may include two one-piece flexible supports 236a and 236B attached on each side of the prism. Another design is shown in fig. 5C and 5D. Fig. 5C shows an isometric exploded view of another embodiment of the OPFE actuation sub-assembly 260', where the OPFE is in the form of a mirror 208. Fig. 5D shows the assembled actuation subassembly 260' in a side view. The actuation subassembly 260' includes a hinge spring having two sets of leaf springs mounted on each side of the mirror, a first set having two spring members 240a and 240b perpendicular to each other, and a second set having two spring members 240c and 240d perpendicular to each other. The axis of rotation will surround a virtual line drawn between the intersections of each set of springs 240a-b and 240 c-d. Fig. 5E schematically shows the AF and OIS movement of the lens module and the OIS tilt movement of the OPFE.

The hinge spring of any of the embodiments presented can convert any direction of force parallel to the X-Z plane into a torque about the Y-axis, thereby producing a tilt about the Y-axis.

As described with reference to fig. 5C and 5D and as described below, in operation, a lorentz force may be applied between the coil 244 and the magnet 242 to move the magnet 242 in the direction indicated by arrow 254 (fig. 5D). This force (and magnet movement) is then translated by the hinge into a tilting motion about the Y-axis indicated by arrow 256 (fig. 5D). This movement is measured by the hall bar sensor 246. In camera module 200, the fourth actuator is positioned such that the applied force is in the + X-Z direction or the-X + Z direction (at 45 degrees to the X and Z axes, see "magnetically operated" section below). However, in other examples, the fourth actuator may be oriented such that the force is directed at any angle in the X-Z plane, so long as a torque is applied about the hinge axis 232 (e.g., the fourth actuator as shown in the embodiment of fig. 5A). The actuators and hall bar sensors of camera module 200 are listed in table 1.

TABLE 1

In accordance with the presently disclosed subject matter, camera module 200 further includes or is otherwise operatively connected to at least one controller (e.g., controller 314) configured to control the operation of lens and OPFE actuation subassemblies 230 and 260 so as to produce movement to compensate for camera shake that tilts the camera module when in use, thereby providing OIS. The controller is configured to receive sensed data indicative of the lens and OPFE positions and tilt data from the gyroscope and, based on the received data, generate instructions for causing the actuation sub-assemblies 230 and 260 to produce movement of the lens module and OPFE that compensates for the unintentional tilt of the folded camera module (and thus provides OIS).

The OPFE tilt compensates for the tilt of the camera about the Y-axis. Movement of the folded lens module in the Y direction compensates for tilt of the camera about the Z axis. The controller receives data about the tilt around Y and tilts OPFE accordingly about the Y axis.

The controller receives data regarding tilt around Z and moves the lens module in the Y direction accordingly. The lens module may be undesirably tilted about the X-axis. As explained further below, in some examples, the controller may be configured to receive data indicative of such unwanted tilt and provide commands to the actuation subassemblies 230 and 260 in order to generate a tilting force to tilt in a direction opposite to the unwanted tilt.

Fig. 6 illustrates the following various views of another embodiment of the OPFE actuation subassembly, numbered 290, according to an example of the presently disclosed subject matter: (a) an isometric view, (b) an exterior side view, (c) an interior side view, and (d) a bottom isometric view, wherein the OPFE is in the form of a prism 308 having a reflective surface 310.

The OPFE actuation sub-assembly 290 includes a suspension structure that includes four flexible suspension members 292a-d that suspend the prism 308 above the base 310. The flexible suspension members 292a-d are similar to the flexible suspension members 216a-d except that they are not parallel but rather are angled. Therefore, they are called "inclined suspension members". The inclined suspension members 292a-d are fixedly mounted on the base 310 at one respective member and attached to the prism at the other member by hinge points 298a and 298b and by side panels 296a and 296 b. In particular, the inclined suspension members 292a and 292b are attached to side panel 296a by hinge point 298a, and the inclined suspension members 292c and 292d are attached to side panel 296b by hinge point 298 b. The side panels are fixedly coupled to opposite sides of the prism. The inclined suspension members 292a-d allow the prism 308 to tilt about a (virtual) hinge axis 294 that is parallel to or along the Y-axis. The actuation sub-assembly 290 further includes a "fourth" actuator that includes a magnet 344 rigidly coupled to the prism 308 and a coil 346 rigidly coupled to the base 298. The actuator functions with similar capabilities as the fourth actuator, which includes a magnet 244 and a coil 246.

In operation, a lorentz force may be applied between the coil 344 and the magnet 346 to move the magnet 346 to the left (arrow 312) or to the right (arrow 314). This force (and magnet movement) is then converted by the inclined suspension member into a tilting ("simple pendulum") motion about axis 294. The tilt may typically be +1 from the prism's null position (rest position). As explained above, the movement is measured by a hall bar (not shown). Such an embodiment allows for increased sensitivity of the hall bar to tilt actuation by increasing the relative motion between the magnet 244 and the hall bar.

Optical operation of actuator element

In compact cameras, focusing, in particular auto-focusing (AF), is performed by shifting the entire lens module with respect to the camera image sensor such that the following equation is satisfied:

where "f" is the focal length, "u" is the distance between the object and the lens, and "v" is the distance between the lens and the image sensor. In camera module 200, focusing (and auto-focusing) may be performed by shifting lens module 204 along the Z-axis.

As disclosed herein, OIS is configured to compensate for camera shake in six degrees of freedom (X-Y-Z, roll, yaw, and pitch) with camera module offset. However, as mentioned above, linear motion in X-Y-Z has a negligible effect on image quality and no compensation is required. Yaw motion of the camera module (tilting about the Z-axis in camera module 200) causes the image to move along the Y-axis on the image sensor. The yaw motion may then be compensated in camera module 200 by shifting lens module 204 along the Y-axis. Pitching motion of the camera module (tilting about the Y-axis in camera module 200) will cause the image to move on the sensor along the X-axis. The pitch motion may then be compensated in the camera module 200 by tilting the prism 206 around the Y-axis.

Magnetic operation of actuator elements

We now describe the operation of each of the four actuators by describing the operation of the first actuator in detail and by way of example. The operation of the second, third and fourth actuators is similar. Fig. 7 shows the elements of the first actuator, namely the coil 224a and the magnet 222a and the associated hall bar 226 a. The coil 224a may have the shape of, for example, a disk-like rectangle (stadium) such that it has one long vertex 310 and one short vertex 312. According to one example, the coils 224a may be made of copper wire coated with a thin layer (coating) of plastic having an inner/outer diameter in the range of 40-60 μm, respectively, with each coil having several tens of turns, such that the total resistance is typically on the order of 10-30 ohms per coil. The magnet 222a may be made of, for example, neodymium alloy (e.g., Nd)₁₂Fe₁₄B) Or samarium cobalt alloys (e.g., SmCo)₅) And (3) forming the permanent magnet. The magnet 222a may be fabricated (e.g., sintered) such that it changes the magnetic pole direction: the left north magnetic pole faces the negative X direction and the right north magnetic pole faces the positive X direction. Such "pole changing" magnets are known in the art and have been described, for example, in PCT patent application WO2014/100516a 1.

Fig. 8 and 9A show an isometric view and a side view, respectively, of the first actuator along the section a-a shown in fig. 7. The coil 224a is shown to be 60 μm in diameter with 48 coil turns. In FIG. 9A, the dot marks cause current flow out of the plane of the page toward the reader (positive Z direction), while the "x" marks indicate current flow in the negative Z direction. Indicating the magnetic pole of the magnet 222a and the position of the hall bar 226 a.

Fig. 9B shows the magnetic simulation along the same a-a section, where the arrows show the magnetic field direction. The Lorentz force is known to be equal to:

F＝I/dl×B

where I is the current in the coil, B is the magnetic field

Are wire elements. Thus, it can be seen that for the indicated current/magnet state, a force is exerted by the magnet on the coil, primarily in the negative Y direction. According to newton's third law, an equal negative force, mainly in the positive Y direction, is applied to the magnet by the coil.

In the embodiment presented here, the hall bar is located in the vacant area in the middle of the coil 224 a. In other embodiments, the hall bar may be located in another position (e.g., near the coil) as long as it is magnetically coupled to the corresponding magnet element.

Mechanical structure of four-wire spring

A mechanical structure comprising four circular wires may be used for in-plane movement in an OIS mechanism, see for example the applicant's published PCT patent application WO2015/060056, the description and drawings of which are incorporated herein by reference in their entirety. Table 2 below lists examples of first motion modes in all six degrees of freedom for a wire having a diameter in the range of 50 to 100 μm, for example, made of metal (e.g., stainless steel alloy) and carrying a total mass of 0.5-1g of a biaxial actuating assembly.

Motion pattern	Range of spring constant	Frequency range
			X	～250000N/m	About 300Hz to about 4000Hz
Y	40N/m to 60N/m	30Hz to 60Hz
			Z	40N/m to 60N/m	30Hz to 60Hz
Tilting about X	～0.001N*m/rad	60Hz to 100Hz
			Inclined about Y	～5N*m/rad	500Hz to 6000Hz
Tilting about Z	～1.25N*m/rad	About 300Hz to 4000HZ

TABLE 2

The typical frequency range of motion in the three modes, the Y-mode, the Z-mode and the "tilt around X" mode, is much lower than the other three modes. This means that the motion in the X mode, "tilt around Y" mode, and "tilt around Z" mode is physically stiffer and less likely to occur with forces as low as those present in the system (on the order of 0.01N).

As explained above, movement along the Y-axis allows OIS to be performed, while movement along the Z-axis allows AF to be performed. In known single-aperture camera modules (e.g. as described in PCT/IB 2014/062181), tilting movements around the X-axis (in the embodiment shown here, an axis parallel to the first optical axis) do not affect the image, since the lens module is axisymmetric around the X-axis. In embodiments of the folded lens camera disclosed herein, the X-axis lies in a plane containing the first and second optical paths and is perpendicular to the second optical axis. In the camera disclosed herein, X-axis tilt may cause image distortion or offset, and is therefore undesirable. Therefore, we describe two "unwanted X-axis tilt" prevention methods below.

The first way to prevent X-axis tilt is to actively counteract it. The method is described with reference to the camera module 200. As explained above, operating the first actuator generates a force on magnet 222a in the ± Y-direction, while operating the second and third actuators generates a force on magnets 222b and 222c in the ± Z-direction. However, since the force exerted on the magnets is also exerted on the lens actuation subassembly 230, which is a rigid body, the translation of the force on each magnet is also converted into a torque on the center of mass of the lens actuation subassembly 230. Table 3 shows the results of the force applied to each of the magnets 222a-c versus the center of mass of the lens actuation sub-assembly 230. Using a combination of three (first, second and third) actuators can generate a force in the Z-Y plane and a torque around the X-axis such that the desired motion is achieved, i.e. a Y motion for OIS is generated, a Z motion for auto-focus and to clear any unwanted X-axis tilt is generated.

TABLE 3

A second method of preventing X-axis tilt is "passive" and is based on reducing the torque forces generated by the first, second and third actuators. This method is schematically illustrated using the actuator arrangement shown in fig. 10 and 11.

Fig. 10 shows a lens barrel 1014 carrying a lens module 1004 having three (first, second and third) actuator components similar to the actuators in the above embodiments ( magnets 1022a, 1022b and 1022c located directly above coils 1024a, 1024b and 1024c, respectively). An actuator comprising these elements does not produce unwanted tilt around the X-axis. Note that magnet 1022b and coil 1024b are shown here as extending substantially (i.e., along the length dimension) across the width (in the Y-direction) of the lens barrel. This arrangement allows the magnet and coil to be positioned between the lens barrel and the sensor. This is advantageous because if even a part of the actuator is positioned below the lens barrel, the total height of the module (in the X direction) increases below the required height. For example, the length of magnet 1022b and coil 1024b in the Y direction may be about 7mm to 8mm, and the width of magnet 1022b and coil 1024b in the Z direction may be about 2mm to 3 mm. For example, the height of all coils is about 0.5 mm. The arrangement of the first, second and third actuators minimizes the torque on the center of mass of the lens actuation sub-assembly. That is, these actuators do not produce unwanted tilt about the X-axis. Table 4 shows the translation of the force on each of magnets 1022a-c to the center of mass of the lens actuation sub-assembly.

TABLE 4

Fig. 11 shows an arrangement for lens actuation with two actuators according to an example of the presently disclosed subject matter. The actuator arrangement uses only two (e.g., first and second) of the actuators in fig. 10. This arrangement is simpler because it can achieve the same result while removing one actuator from the arrangement of fig. 10.

Fig. 12A schematically illustrates an isometric view of another folded camera module, numbered 1100, according to an example of the presently disclosed subject matter. Note that the X-Y-Z coordinate system is oriented differently than in fig. 1-11. The folded camera module 1100 includes an image sensor 1102 having an imaging surface in the X-Y plane, a lens module 1104 having an optical axis 1106 defined above as "second optical axis", and an OPFE1108 having a surface plane 1110 that is tilted to the image sensor surface, such that light arriving along a first optical path or direction 1105 is tilted by the OPFE to the second optical axis or direction 1106.

Fig. 12B shows a folded camera module 1100 with the folded lens module removed from its chassis. Fig. 12C shows the folded lens module (a) in a conventional isometric view and (b) inverted.

In one embodiment, camera module 1100 includes a lens actuation subassembly for moving lens module 1104 in the Z direction for auto-focusing. The subassembly may include a single actuator having a magnet 1122ab and a coil 1124 b. In other embodiments, camera module 1100 may include lens actuation subassemblies for moving lens module 1104 in the Y-Z plane. However, in contrast to the 3-actuator lens actuation subassembly shown in fig. 3 and 10, the actuation subassembly in folded camera module 1100 includes four actuators operating on the lens module. In other words, an additional "fifth" actuator is added to the first, second and third actuators of the lens actuation subassembly: here, the first actuator includes a magnet 1122ab and a coil 1124a, the second actuator includes a magnet 1122ab and a coil 1124b as shown in fig. 1124b, and the third actuator includes a magnet 1122c and a coil 1124 c. The added ("fifth") actuator includes magnet 1122d and coil 1124 d. The magnet and coil arrangement is similar to that in fig. 10 in that the magnet 1122b and coil 1124b are located between the lens module and the image sensor, enabling efficient Z-axis actuation (for auto-focus). Actuators comprising magnets 1122ab and coils 1124a, 1122ab and coils 1124b, and 1122d and coils 1124d may be actively used to prevent unwanted tilting about the X-axis. Two hall bar sensors 1126b' and 1126b "measure displacement in the Z direction and tilt about the X axis. The hall bar sensor 1126c measures displacement in the Y direction.

The long coil dimension in the Y-direction provides high efficiency for the autofocus action in the Z-direction. To illustrate the coil power (P)_e) And how the mechanical force (F) depends onIn terms of coil size, the simple case of a single turn coil can be analyzed. The coil having a wire cross-sectional area S is disposed in the Y-Z plane and has an exemplary rectangular shape with a length L_yIs parallel to Y and has a length L_zIs parallel to Z. The permanent magnet (ferromagnet) generating the magnetic field in the coil is designed such that the force (F) between the coil and the magnet in the Z direction_z) Maximized, which is caused by the current I flowing in the coil. In this case, F_z＝2k₁IL_yWherein k is₁Is a constant that depends on (among other things) the magnetic field strength. Coil power P_e＝2k₂l²S(L_z+L_y) Wherein k is₂Are different constants. High efficiency magnetic engine for low P_eHaving a high F_z. Efficiency factor (E)_f＝F_z/P_c) Can be derived as:

E_f＝((k₁ ²)*S)/(k₂*F_z)*L_y/(l+L_z/L_y)

or by using I ═ F_z/(2k₁L_y)

E_f＝[((k₁ ²)*S)/(k₂*F_z)]*L_y/(l+L_z/L_y)

From the above, it is clear that if L is_yIncreased by a factor of 2 (everything else being equal), then E_fWill increase by a factor of more than 2. Therefore, the longer the coil in the Y direction, the better. The positioning of the magnet 1122c between the lens module and the image sensor advantageously allows the magnet to be elongated in the Y-direction to approximately the width of the lens module carrier. For example, coil 1124c has a long dimension or long apex (typically about 7mm to 8mm) in the Y direction and a short dimension or short apex (typically about 2mm to 3mm) in the Z direction. In general, for a single or multi-turn coil, the longer the coil in the direction perpendicular to the magnetic force, the higher will be the efficiency of the magnetic motor using the coil.

The positioning of the magnet of the AF actuator between the lens module and the image sensor may cause light arriving along the optical axis (Z-axis) of the lens to undergo light reflection. Such reflections may affect the image acquired at the folded camera image sensor. To prevent such reflections, the magnet (i.e., magnet 1122C) may be coated with an absorptive and scattering coating (fig. 12C and 13), such as the Actar Black Velvet paint manufactured by keler gater Actar, inc. Alternatively or additionally, the magnet may have a wave or other shaped perturbation to further scatter the reflected light. Alternatively, the above corrugated sheet structure ("yoke") 1130 with absorbing and scattering coatings may be attached to the magnet.

In summary, some camera embodiments disclosed herein include at least the following features:

1. fully closed loop AF + OIS functionality

2. Ultra thin design without height constraint

3. And (3) low-cost design:

integrated circuits are used for OIS, AF and camera sensors.

A fully passive moving mass, without the need to transmit power to the moving object.

While the present disclosure has been described in terms of certain embodiments and generally associated methods, alterations and permutations of the embodiments and methods will be apparent to those skilled in the art. For example, although the incorporation of a folded camera module into a dual-aperture camera is described in considerable detail herein, a folded camera module may be incorporated into a multi-aperture camera having more than two camera modules. For example, although examples using hall bars as position sensors are described in detail, other position sensors (e.g., microelectromechanical system (MEMS) type position sensors) may be used for the purposes set forth herein. The present disclosure should not be construed as limited to the particular embodiments described herein.

It is emphasized that citation or identification of any reference in this application shall not be construed as an admission that such reference is available or allowed as prior art.

Claims (20)

1. An Optical Path Folding Element (OPFE) actuation subassembly, comprising: a) a voice coil motor (VCM) actuator for actuating the OPFE to tilt about a virtual hinge axis located outside the OPFE, the VCM actuator comprising a magnet rigidly coupled to the OPFE and a rigid a coil that is ground coupled to the base; and b) Hall-bar, which is co-located with the coil and used to measure the magnetic field within the Hall-bar in relation to the amount of tilt of the OPFE, wherein the sensitivity of the Hall-bar measurement is increased by increasing the magnet and the relative movement between the Hall-bar, which can be achieved by positioning a virtual hinge axis outside the OPFE. 2. The OPFE actuation subassembly of claim 1, wherein the relative movement between the magnet and the Hall-bar is within a tilt range of ±1° from the rest position of the OPFE. 3. The OPFE actuation sub-assembly of claim 1, further comprising a suspension structure having a plurality of flexible inclined suspension members suspending the OPFE above the base. 4. The OPFE actuation sub-assembly of claim 3, wherein the plurality of flexible tilt suspension members comprises 4 flexible tilt suspension members. 5. The OPFE actuation subassembly of claim 3, wherein each of the inclined suspension members is fixedly mounted to the base at a first member end and attached to the OPFE at a second member end. 6. The OPFE actuation subassembly of claim 5, wherein each of the tilt suspension members attached to the OPFE at the second member end is fixedly coupled to the OPFE by connected to the side panels on the side. 7. The OPFE actuation subassembly of claim 1, wherein the OPFE is a prism. 8. The OPFE actuation subassembly of claim 3, wherein the suspension structure is designed to prevent the OPFE from tilting or a different translation than tilting about the virtual hinge. 9. A folding camera comprising: a) an optical path folding element (OPFE) for folding the optical path from a first direction to a second direction; b) lens; c) image sensor; d) Actuating sub-assemblies, including: A voice coil motor (VCM) actuator for actuating the tilt of the OPFE about a virtual hinge axis located outside the OPFE for optical image stabilization (OIS), wherein the VCM actuator includes a rigidly coupled to a magnet of the OPFE and a coil rigidly coupled to the base; a hall-bar co-located with the coil and used to measure the magnetic field within the hall-bar in relation to the amount of tilt of the OPFE, wherein the sensitivity of the hall-bar measurement is measured by increasing the magnet and the The relative movement between the Hall bars is increased, which can be achieved by positioning a virtual hinge axis outside the OPFE. 10. The foldable camera of claim 9, wherein the relative movement between the magnet and the Hall-bar is within a tilt range of ±1° from the rest position of the OPFE. 11. The folding camera of claim 9, further comprising a suspension structure having a plurality of flexible inclined suspension members that suspend the OPFE above the base. 12. The foldable camera of claim 11, wherein the plurality of flexible tilt suspension members comprises 4 flexible tilt suspension members. 13. The foldable camera of claim 11, wherein each of the tilt suspension members is fixedly mounted to the base at a first member end and attached to the OPFE at a second member end. 14. The foldable camera of claim 13, wherein each of the tilt suspension members attached to the OPFE at the second member end is by fixedly coupled to a side of the OPFE connected to the side panel. 15. The folding camera of claim 9, wherein the OPFE is a prism. 16. The foldable camera of claim 11, wherein the suspension structure is designed to prevent the OPFE from tilting or a different translation than tilting about the virtual hinge. 17. The foldable camera of claim 9, included in a smartphone. 18. The foldable camera of claim 10, included in a smartphone. 19. The foldable camera of claim 11, included in a smartphone. 20. The foldable camera of claim 12, included in a smartphone.

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